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Systematic characterization of wing mechanosensors that monitor airflow and wing deformations

Joseph M. Fabian, Igor Siwanowicz, Myriam Uhrhan, Masateru Maeda, Richard J. Bomphrey, Huai‐Ti Lin

2022iScience42 citationsDOIOpen Access PDF

Abstract

Animal wings deform during flight in ways that can enhance lift, facilitate flight control, and mitigate damage. Monitoring the structural and aerodynamic state of the wing is challenging because deformations are passive, and the flow fields are unsteady; it requires distributed mechanosensors that respond to local airflow and strain on the wing. Without a complete map of the sensor arrays, it is impossible to model control strategies underpinned by them. Here, we present the first systematic characterization of mechanosensors on the dragonfly's wings: morphology, distribution, and wiring. By combining a cross-species survey of sensor distribution with quantitative neuroanatomy and a high-fidelity finite element analysis, we show that the mechanosensors are well placed to perceive features of the wing dynamics relevant to flight. This work describes the wing sensory apparatus in its entirety and advances our understanding of the sensorimotor loop that facilitates exquisite flight control in animals with highly deformable wings.

Topics & Concepts

WingAirflowAerospace engineeringAeronauticsEngineeringMechanical engineeringAerospace and Aviation TechnologyBiomimetic flight and propulsion mechanismsAerospace Engineering and Energy Systems
Systematic characterization of wing mechanosensors that monitor airflow and wing deformations | Litcius